KR101798757B1 - Synchronization device in a high voltage direct current system and method thereof - Google Patents

Abstract

A synchronizing device in an HVDC system is for synchronizing the switching control on a plurality of arms. The synchronizing device in the HVDC system includes a plurality of valve control units corresponding to a plurality of arms and a plurality of sensing signals sensed from various positions of at least one system of the HVDC system using a PLL algorithm based on a plurality of sensing signals, And a first measurement system for simultaneously transmitting the synchronization signal to the plurality of valve controls.

Description

Technical Field [0001] The present invention relates to a synchronizing device in a HVDC system,

The present invention relates to a synchronizing apparatus and method in an HVDC system that can prevent unnecessary resource waste.

HVDC (High Voltage Direct-Current Transmission) has advantages such as long-distance transmission, asynchronous grid connection, submarine cable use and power control compared to HVAC (High Voltage Alternating-Current transmission) Application cases are steadily increasing.

The high-voltage DC transmission system converts AC power into DC power at the transmission side, and converts the DC power into AC power at the demand side and supplies it to the customer.

A high voltage DC transmission system includes a converter including a plurality of arms for converting AC power into DC power or DC power into AC power and a plurality of controllers for controlling the converter.

Each of the plurality of controllers generates a synchronization signal by performing a PLL (Phase Locked-Loop) algorithm based on the AC voltage and / or current received from the AC system, and controls the arm of the converter according to the synchronization signal And outputs a signal.

As described above, in the conventional high-voltage DC transmission system, each controller generates a synchronization signal by itself, resulting in a large amount of resources being wasted on the system side and acting as a load on each controller.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a synchronization apparatus and method in an HVDC system that can prevent resource waste through efficient synchronization management.

According to an embodiment of the present invention, the measurement system includes: a signal conversion unit that converts a sensing signal received from a plurality of sensing units installed in at least one system into a digital signal; A signal processing unit for calculating a filter data value from the digital signal and performing a PLL algorithm based on the calculated filter data value to generate a synchronization signal; And a signal transmitter for simultaneously transmitting the generated synchronization signal to a plurality of valve controllers corresponding to the plurality of arms of the converter.

According to another embodiment of the present invention, a synchronization device in a HVDC system for synchronization of switching control for a plurality of arms comprises: a plurality of valve control sections corresponding to the plurality of arms; And a controller for generating a synchronization signal using a PLL algorithm based on a plurality of sensing signals sensed at various positions of at least one system of the HVDC system and for simultaneously transmitting the generated synchronization signal to the plurality of valve controllers System.

According to another embodiment of the present invention, a synchronization method in an HVDC system for synchronization of switching control for a plurality of arms comprises the steps of: in a first measurement system, detecting a plurality of HVDC systems from a plurality of locations of at least one system of the HVDC system Generating a synchronization signal using a PLL algorithm based on the sensing signal of the synchronization signal; In the first measurement system, simultaneously transmitting the generated synchronization signal to a plurality of valve controllers; And, in each of the valve controls, transmitting a gate command to the corresponding arm in accordance with the synchronization signal.

In the present invention, since a synchronization signal is generated in the measurement system and simultaneously transmitted to each valve control unit, a gate command can be simultaneously transmitted to each arm in each valve control unit, so that a plurality of submodules included in each arm are simultaneously switched- It is possible to prevent power waste due to loss.

The present invention has at least two measurement systems to perform a function in place of an error measurement system when an error occurs in one measurement system, thereby eliminating the need to replace a separate measurement system, Can be improved.

1 is a block diagram illustrating a synchronization apparatus in an HVDC system according to a first embodiment of the present invention.
2 is a block diagram illustrating the arms included in the converter of FIG.
FIG. 3 shows a circuit diagram of a submodule included in the arm of FIG.
4 is a block diagram showing the detailed structure of the valve control unit of FIG.
5 is a block diagram showing the detailed structure of the measurement system of FIG.
Figure 6 is a flow chart illustrating the method of operation of the measurement system of Figure 1;
7 is a flowchart illustrating a synchronization method in a synchronizing apparatus in an HVDC system according to the first embodiment of the present invention.
8 is a block diagram illustrating a synchronization apparatus in an HVDC system according to a second embodiment of the present invention.

Hereinafter, embodiments related to the present invention will be described in detail with reference to the drawings. The suffix "part," "module," and " part "for components used in the following description are given or mixed in consideration of ease of specification only and do not have their own distinct meanings or roles .

1 is a block diagram illustrating a synchronization apparatus in an HVDC system according to the present invention.

Referring to FIG. 1, the synchronizing apparatus in the HVDC system according to the present invention may include a measurement system 12, a system control unit 10, and a valve control unit 20.

The synchronization device may further include a sensing unit 98 for detecting a voltage and / or a current of the AC system or the DC system. The sensing unit 98 may be installed at various positions or places in the AC system or the DC system so that the voltage and / or the current of the AC system or the DC system can be detected from each of the sensing units 98 provided at each position or place.

The synchronizing apparatus may further include a converter 90 for performing a switching operation under the control of the valve control unit 20 to convert AC power into DC power.

The converter 90 includes a plurality of arms 91 to 96, and each arm 91 to 96 may include a plurality of submodules as shown in FIG.

Each of the sub-modules SM_1 to SM_n may be a half type sub-module (FIG. 3A) or a full type sub-module (FIG. 3B).

3A, the half-type submodule may include two switches S1 and S2, two diodes D1 and D2, and a capacitor CM.

Each of the diodes D1 and D2 is connected in parallel to each of the switches S1 and S2 to prevent backflow of the current to prevent malfunction of the switches S1 and S2.

The capacitor CM serves to charge the input voltage when the first and second switches S1 and S2 are turned on and to discharge the charged voltage when the first and second switches S1 and S2 are turned off .

The first and second switches S1 and S2 may be turned on or off by a gate signal provided in the drivers 12 to 17. [ When the first and second switches S1 and S2 are turned on, an AC voltage can be charged in the capacitor CM.

Each of the first and second switches S1 and S2 may be an insulated gate bipolar transistor (IGBT) or a thyristor, but is not limited thereto.

As shown in FIG. 3B, the full type submodule may include four switches S1 to S4, four diodes D1 to D4, and a capacitor CM.

Each of the diodes D1 to D4 may be connected in parallel to each of the switches S1 to S4.

For example, when the first and fourth switches S1 and S4 are turned on, the positive AC voltage is charged in the capacitor CM, and when the second and third switches S2 and S3 are turned on, Although the AC voltage can be charged to the capacitor CM, this is not limited thereto.

The modular multi-level converter 90 of the present invention may be provided with two three-phase arm bridge connections, but this is not limited thereto.

In the present invention, the switching frequencies of the sub-modules SM_1 to SM-n are uniformly maintained by the selective switching control of the sub-modules SM_1 to SM-n, so that the life of the converter 90 can be extended.

Referring to FIG. 1, the valve control unit 20 may include a plurality of valve control units 30 to 80.

Specifically, as shown in Fig. 4, each of the valve controllers 30 to 80 may include a main controller 32 and a plurality of valve controllers 34_1 to 34_m.

The main controller 32 can control the plurality of valve controllers 34_1 to 34_m. For example, the main controller 32 may provide the gate command GC provided from the system control unit 10 to each of the plurality of valve controllers 34_1 to 34_m, respectively. For example, the main controller 32 may provide the synchronization signal SC provided from the measurement system 12 to each of the plurality of valve controllers 34_1 to 34_m, respectively.

Each of the valve controllers 34_1 to 34_m may output a gate command GC according to the synchronizing signal SC and provide the output gate command GC to the corresponding arm.

For example, the first to sixth valve control sections 30 to 80 may correspond to the first to sixth arms 91 to 96, respectively.

Each of the first to sixth valve control sections 30 to 80 includes a plurality of valve controllers 34_1 to 34_m for example so that the plurality of submodules included in each of the first to sixth arms 91 to 96 also include a plurality of And may be grouped into a plurality of sub-module groups corresponding to the respective valve controllers 34_1 to 34_m.

The gate command GC outputted from each of the plurality of valve controllers 34_1 to 34_m included in the first valve control unit 30 may be provided as a plurality of submodule groups included in the first arm 91. [ The plurality of submodules included in each of the plurality of submodule groups of the first arm 91 can be switching-controlled in response to the gate command GC.

In this manner, the gate command (GC) output from each of the plurality of valve controllers 34_1 to 34_m included in the sixth valve control unit 80 is provided as a plurality of submodule groups included in the sixth arm 96 . A plurality of submodules included in each of the plurality of submodule groups of the sixth arm 96 can be switching-controlled in response to the gate command GC.

As described above, the plurality of sub-modules of the arms 91 to 96 are switched and controlled in accordance with the gate command GC provided from the respective valve control units 30 to 80 so that the AC power can be converted into the DC power.

On the other hand, the switching operation of the submodules included in each of the arms 91 to 96 must be performed at the same time. If the switching operation of the submodule included in each of the arms 91 to 96 is not performed at the same time, a power loss occurs and conversion efficiency in which AC power is converted into DC power is reduced, resulting in power wastage.

A synchronizing signal SC is required to make the switching operation of the submodules contained in each of the arms 91 to 96 be performed at the same time.

In the synchronizing apparatus according to the present invention, a synchronizing signal SC can be generated in the measuring system 12. [

The input terminal of the measurement system 12 may be connected to the output terminal of the sensing unit 98. Since the sensing unit 98 is installed in a plurality of power plants or a plurality of substations, a plurality of sensing units 98 may be installed. The sensing unit 98 can detect an AC voltage and / or a current of an AC system or a DC system and output the detected signal as a sensing signal (Sensing). The output sensing signal (Sensing) may be provided to the measurement system 12. The sensing signal (Sensing) may be an analog signal.

The output terminal of the measurement system 12 may be connected to the input of each of the system control unit 10 and the valve control unit 20. More specifically, the output terminal of the measurement system 12 may be connected to the inputs of each of the first to sixth valve controllers 30 to 80 as well as the system controller 10. For individual connections between the system and the first through sixth valve controls 30-80, the measurement system 12 may include, but is not limited to, seven output stages for synchronization output. The first output terminal may be connected to the input terminal of the system control unit 10 and the second to seventh output terminals may be connected to the first to sixth valve control units 30 to 80. [ Therefore, the synchronous signal SC output through each output terminal of the output system can be simultaneously supplied to the system control unit 10 and the first to sixth valve control units 30 to 80. [

Although Fig. 1 shows six valve control units 30 to 80, more or less of them may be used.

The synchronization signal SC may be a digital signal.

The measurement system 12 measures the voltage and / or current of the AC system or the DC system on the basis of the sensing signal Sensing provided from each sensing unit 98, and based on the measured voltage and / or current, Can be performed.

The PLL algorithm can be performed by a known method.

The measurement system 12 generates the synchronization signal SC through the PLL algorithm and the generated synchronization signal SC can be simultaneously provided to the system control unit 10 and the first to sixth systems.

The system control unit 10 provides the gate command GC to the first to sixth valve control units 30 to 80 in accordance with the synchronizing signal SC and each of the first to sixth valve control units 30 to 80 performs synchronous The first to sixth arms 91 to 96 of the converter 90 can provide the gate command GC provided from the system control unit 10 in accordance with the signal SC.

The plurality of submodules included in each arm 91 to 96 can be switched and controlled in response to the gate command GC provided to each arm 91 to 96 according to the synchronous signal SC so that the DC power of the AC power It is possible to improve the conversion efficiency to the power consumption and to prevent power waste.

5 is a block diagram showing the detailed structure of the measurement system of FIG.

5, the measurement system 12 may include a signal converter 14, a signal processor 16, and a signal transmitter 18.

The signal converting unit 14 may receive the sensing signal Sensing detected by the plurality of sensing units 98. [

The received sensing signal (Sensing) may be an analog signal.

The signal converting unit 14 may convert the sensing signal (Sensing), which is an analog signal, into a voltage signal and / or a current signal, which are digital signals.

The signal converting unit 14 may be an analog-to-digital converter (ADC).

The ADC may be provided as many as the number of the sensing units 98. For example, when there are 100 sensing units 98, 100 ADCs corresponding to the sensing units 98 may be provided.

The sensing signal (Sensing) can be converted into a voltage signal and / or a current signal which is a digital signal by each ADC.

The plurality of ADCs are configured in parallel so that the sensing signal (Sensing) can be simultaneously converted into a voltage signal and / or a current signal by a plurality of ADCs.

The signal processing unit 16 may process the voltage signal and / or the current signal to calculate the filter data value. In addition, the signal processor 16 can perform PLL algorithm using the filter data value to confirm the synchronization start point. When the synchronization start point is confirmed, the synchronization signal SC can be generated based on the synchronization start point.

As a PLL algorithm, a second order generalized integrator (SOGI) or a synchronous reference frame PLL (SRE) is used, but the present invention is not limited thereto.

The signal transfer unit 18 may transmit the generated synchronization signal SC to the system control unit 10 and the first to sixth valve control units 30 to 80. [

Figure 6 is a flow chart illustrating the method of operation of the measurement system of Figure 1;

5 and 6, the signal converting unit 14 receives the sensing signal Sensing provided from the sensing unit 98 (S110), and converts the sensed signal (Sensing) into a voltage signal And / or generate a current signal (S120).

The signal processing unit 16 may perform preprocessing based on the voltage signal and / or the current signal to calculate a filter data value (S130). The filter data value may be a Root Mean Square (RMS) value for a voltage signal and / or a current signal that is converted and accumulated from a sensing signal (Sensing) received from the measurement system 12 during a predetermined period, but is not limited thereto.

The signal processing unit 16 may perform a PLL algorithm (S140) and check the synchronization start point based on the filter data value (S150).

When the synchronization start point is confirmed, the signal processing unit 16 can generate the synchronization signal SC based on the synchronization start point (S160).

The signal transmission unit 18 may transmit the synchronization signal SC to the first through sixth valve control units 30 through 80, respectively (S170).

Each of the first to sixth valve control sections 30 to 80 may transmit the gate command GC to the first to sixth arms 91 to 96 of the converter 90 in accordance with the synchronization signal SC. The submodules included in the first to sixth arms 91 to 96 are switching-controlled in response to the gate command GC so that AC power can be converted to DC power.

If the synchronization start point is not confirmed, the signal transmitting unit 18 may transmit the preprocessed values calculated in S120 to the first to sixth valve controllers 30 to 80, respectively (S180). Each of the first to sixth valve control sections 30 to 80 may process the pre-processing value according to a predetermined processing procedure, but it is not limited thereto.

S110 to S180 may be repeatedly performed at regular intervals, for example, at intervals of 96 ms. By repeating this cycle, the synchronization start point is tracked and a synchronization signal SC based on the synchronization start point can be generated.

7 is a flowchart illustrating a synchronization method in a synchronizing apparatus in an HVDC system according to the present invention.

Referring to FIGS. 1 and 7, the measurement system 12 may receive a sensing signal (S210). The sensing signal (Sensing) may be transmitted from a plurality of sensing units 98 installed in a power station or a substation.

The measurement system 12 may perform a PLL algorithm based on the sensing signal (S210) and generate a synchronous signal SC (S230).

Specifically, the measurement system 12 converts the sensing signal (Sensing) into a current signal and / or a current signal, which is a digital signal, and accumulates the converted voltage signal and / or current signal for a predetermined period to calculate a filter data value , And the PLL algorithm can be performed to confirm the synchronization start point based on the filter data value.

If the synchronization start point is confirmed, the measurement system 12 can generate the synchronization signal SC based on the synchronization start point.

Subsequently, the measurement system 12 can simultaneously transmit the synchronous signal SC to the respective valve control units 30 to 80 (S240).

Each of the valve control units 30 to 80 may transmit a gate command GC sent from the system control unit 10 to each of the arms 91 to 96 in accordance with the synchronization signal SC at step S250. In each of the arms 91 to 96, in response to the gate command GC, a plurality of submodules included in each of the arms 91 to 96 can be controlled to be switched.

According to the present invention, the synchronizing signal SC is generated in the measuring system 12 and simultaneously transmitted to the respective valve controllers 30 to 80 so that the gate command GC is simultaneously supplied to each arm And the plurality of submodules included in each of the arms 91 to 96 are simultaneously switched and controlled to prevent power wastage due to power loss.

8 is a block diagram illustrating a synchronization apparatus in an HVDC system according to a second embodiment of the present invention.

The second embodiment of the present invention is similar to the first embodiment of the present invention except that one more second measurement system 17 is added. Therefore, the description of the components that are duplicated in the second embodiment of the present invention with respect to the first embodiment of the present invention will be omitted.

Referring to FIG. 8, the synchronizing apparatus in the HVDC system according to the second embodiment of the present invention includes a first measuring system 15, a second measuring system 17, a system controller 10, and a plurality of valve controllers 30 To 80).

The sensing unit 98 is installed in a power plant or a substation and detects a voltage and / or a current of an AC system or a DC system and outputs the detected voltage and / or current as a sensing signal to the first and second measurement systems 15 , 17).

Each of the first and second measurement systems 15 and 17 generates a synchronization signal SC using a PLL algorithm based on a sensing signal and outputs the generated synchronization signal SC to a plurality of valve controllers 30 to 80).

One of the first and second measuring systems 15 and 17 may be a master system and the other may be a slave system.

In the following, the first measurement system 15 is a master system and the second measurement system 17 is a slave system, but it is not limited thereto.

Both the first measuring system 15 and the second measuring system 17 transmit the synchronizing signal SC to the plurality of valve controllers 30 to 80 while each of the valve controllers 30 to 80 performs the first measurement The gate command GC can be transmitted to each arm 91 to 96 of the converter 90 in accordance with the synchronization signal SC received from the system 15. [

To this end, each of the valve controls 30 to 80 may be set to recognize the first measurement system 15 as a master system and the second measurement system 17 as a slave system in advance.

The first measurement system 15 may include flag information for identifying the first measurement system 15 together with the synchronization signal SC in the packet to be transmitted to the respective valve controllers 30 to 80.

Similarly, the second measurement system 17 may include flag information, which can identify the second measurement system 17 together with the synchronization signal SC, in the packet and transmit it to the respective valve control units 30 to 80.

Alternatively, the first and second measurement systems 15 and 17 may include status information on whether the packet including the synchronization signal SC is active or standby. The active state indicates that the measurement system is a master system, and the standby state indicates that the measurement system is a slave system. Each of the valve control units 30 to 80 can confirm whether the first and second measurement systems 15 and 17 are master systems or slave systems through the status information.

The second measurement system 17, which is a slave system, may perform digital signal conversion, PLL algorithm execution, and the like according to the synchronization signal SC transmitted from the first measurement system 15 as the master system, but this is not limited thereto .

The first measurement system 15 and the second measurement system 17 are capable of communicating with each other. Thereby, when a fault occurs in the first measuring system 15 and the operation of the first measuring system 15 is impossible, the first measuring system 15 transmits the error information to the second measuring system 17, As shown in FIG.

The second measurement system 17 acquires the master authority based on the error information and generates a synchronization signal (Sensing) based on the sensing signal Sensing transmitted from the sensing unit 98 independently of the first measurement system 15 SC to the valve control units 30 to 80, respectively.

At this time, the packet including the synchronization signal SC may include status information about the active state instead of the standby state. Accordingly, each of the valve controllers 30 to 80 determines that the second measurement system 17 is changed to the master system by generating an error in the first measurement system 15 based on the status information about the active state included in the packet Can be confirmed.

According to the invention, at least two measuring systems (15, 17) are provided so that when an error of one measuring system (15) occurs, the other measuring system (17) By performing the corresponding function, it is not necessary to replace the measurement system 15 in which the error occurred, and the system management efficiency can be improved.

According to an embodiment of the present invention, the above-described method can be implemented as a code that can be read by a processor on a medium on which the program is recorded. Examples of the medium that can be read by the processor include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, etc., and may be implemented in the form of a carrier wave (e.g., transmission over the Internet) .

The embodiments described above are not limited to the configurations and methods described above, but the embodiments may be configured by selectively combining all or a part of the embodiments so that various modifications can be made.

Claims (19)

A signal converting unit for converting a sensing signal received from a plurality of sensing units installed in at least one system into a digital signal;
A signal processing unit for calculating a filter data value from the digital signal and performing a synchronization algorithm based on the calculated filter data value to generate a synchronization signal; And
And a signal transmission unit for simultaneously transmitting the generated synchronization signal to a plurality of valve control units corresponding to the plurality of arms of the converter,
Wherein the filter data value is a Root Mean Square (RMS) value for the digital signal accumulated during a predetermined period. The method according to claim 1,
Wherein the synchronization algorithm is a PLL algorithm. The method according to claim 1,
Wherein the signal transmission unit comprises:
And transmits the generated synchronization signal to the system controller. The method according to claim 1,
Wherein the signal conversion unit comprises:
And a plurality of analog-to-digital converters corresponding to the plurality of sensing units. delete The method according to claim 1,
The signal processing unit,
A synchronization start point is identified based on the filter data value, and a synchronization signal is generated based on the identified synchronization start point. A synchronization device in an HVDC system for synchronization of switching control for a plurality of arms,
A plurality of valve controls corresponding to the plurality of arms; And
A first measurement system for generating a synchronization signal using a PLL algorithm based on a plurality of sensing signals sensed from various positions of at least one system of the HVDC system and simultaneously transmitting the generated synchronization signal to the plurality of valve controllers, / RTI >
Wherein the first measurement system comprises:
A signal converter for converting the plurality of sensing signals into digital signals;
A signal processing unit for calculating a filter data value from the digital signal and performing a PLL algorithm based on the calculated filter data value to generate a synchronization signal; And
And a signal transmission unit for simultaneously transmitting the generated synchronization signal to the plurality of valve control units,
Wherein the filter data value is a Root Mean Square (RMS) value for the digital signal accumulated for a predetermined period of time. 8. The method of claim 7,
And a plurality of sensing units installed at various positions of the at least one system to detect a plurality of sensing signals. delete 8. The method of claim 7,
And a second measurement system for generating a synchronization signal using a PLL algorithm based on the plurality of sensing signals and simultaneously transmitting the generated synchronization signal to the plurality of valve controllers. 11. The method of claim 10,
Wherein one of the first and second measurement systems is a master system and the other is a slave system. 12. The method of claim 11,
The synchronizing signal includes:
Wherein the synchronization information is included in the packet along with the status information for the first and second measurement systems. 13. The method of claim 12,
The status information may include:
An active state indicating that the master system and a standby state indicating that it is a slave system. 12. The method of claim 11,
The synchronizing signal includes:
Wherein the first and second measurement systems are included in a packet together with flag information capable of identifying the first and second measurement systems. 12. The method of claim 11,
In the slave system,
And a synchronization unit in the HVDC system operating according to a synchronization signal transmitted from the master system. 12. The method of claim 11,
Wherein the slave system obtains master authority and operates as a master system when an error occurs in the master system. A synchronization method in an HVDC system for synchronization of switching control for a plurality of arms, each corresponding to a plurality of valve controls,
In a first measurement system, a plurality of sensing signals sensed from different locations of at least one system of the HVDC system are converted into digital signals, filter data values are calculated from the converted digital signals, and the calculated filter data values Generating a synchronization signal using a PLL algorithm based on the synchronization signal;
In the first measurement system, simultaneously transmitting the generated synchronization signal to a plurality of valve controllers; And
And in each of the valve controls, transmitting a gate command to the corresponding arm in accordance with the synchronization signal,
Wherein the filter data value is a Root Mean Square (RMS) value for the sensing signal accumulated for a predetermined period of time. 18. The method of claim 17,
Further comprising the step of, if an error occurs in said first measurement system, obtaining a master right of said first measurement system in a second measurement system and operating as a master system. 19. The method of claim 18,
Wherein operating as the master system comprises:
Generating the synchronization signal; And
And simultaneously transmitting the generated synchronization signal to the plurality of valve control units.

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